Abstract
GroEL is an ATP dependent molecular chaperone that promotes the folding of a large number of substrate proteins in E. coli. Large-scale conformational transitions occurring during the reaction cycle have been characterized from extensive crystallographic studies. However, the link between the observed conformations and the mechanisms involved in the allosteric response to ATP and the nucleotide-driven reaction cycle are not completely established. Here we describe extensive (in total long) unbiased molecular dynamics (MD) simulations that probe the response of GroEL subunits to ATP binding. We observe nucleotide dependent conformational transitions, and show with multiple 100 ns long simulations that the ligand-induced shift in the conformational populations are intrinsically coded in the structure-dynamics relationship of the protein subunit. Thus, these simulations reveal a stabilization of the equatorial domain upon nucleotide binding and a concomitant “opening” of the subunit, which reaches a conformation close to that observed in the crystal structure of the subunits within the ADP-bound oligomer. Moreover, we identify changes in a set of unique intrasubunit interactions potentially important for the conformational transition.
Highlights
GroEL participates in the folding of 5-10% of cellular Escherichia coli proteins by providing an isolated chamber for non-native substrate proteins together with a heptameric ring shaped cochaperonin, denoted GroES [1,2,3,4,5]
We provide a description of the molecular basis for the conformational changes in the GroEL subunit by performing extensive molecular dynamics simulations
The simulations sample the conformational population for the different nucleotide-free and bound states in the isolated subunit
Summary
GroEL participates in the folding of 5-10% of cellular Escherichia coli proteins by providing an isolated chamber for non-native substrate proteins together with a heptameric ring shaped cochaperonin, denoted GroES [1,2,3,4,5]. The first high-resolution X-ray structure was released in 1994 by Braig et al [8], and since numerous structural studies, including X-ray crystallography, cryo-EM, and NMR have been published of different functional states of GroEL (for reviews see [11,12]). On this structural background it has been possible to make predictions and educated hypothesis about the transition pathways during the protein functional cycle. The conformational transitions occurring on the subunit level are substantial, and its trajectory is generally explained in a sequential manner
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